High-speed varifocal objective system



SEARCHROOM BSO-427 uc. n', :u1u K. MACHER HIGH-SPEED VARIFOCAL OBJECTIVE SYSTEM Filed July 1, 196e 5 Sheets-Sheet 1 Karl Macher lnvenlor.

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United States Patent O 3,549,235 HIGH-SPEED VARIFOCAL OBJECTIVE SYSTEM Karl Macher, Bad Kreuznach, Germany, assignor to Jos. Schneider & Co. Optische Werke, Bad Kreuznach, Rhineland, Germany, a corporation of Germany Filed July 1, 1968, Ser. No. 741,773 Claims priority, application Germany, June 30, 1967, 1,572,854, 1,572,855 Int. Cl. G02b 15/14 U.S. Cl. 350-184 13 Claims ABSTRACT OF THE DISCLOSURE Varifocal objective system with a relative aperture of about 1:2 and a varifocal ratio of about 10:1, including a basic multilens objective and a four-component front attachment with two movable negative components bracketed by two substantially fixed positive components;

the first component, which may be limitedly shiftable (in whole or in part) for focusing purposes, includes one or two negative front lenses, a positive singlet, a negative doublet and three further positive singlets; the second component consists of a negative singlet followed by a negative triplet; the third component is a negative doublet; and the fourth component consists of two airspaced positive singlets.

substantially fixed, as appliedto the first component,Y

implies that the latter may be limitedly shiftable, in whole or in part, for focusing purposes as is well known per se.

As more specifically disclosed in my above-identified application and patent, the first component may include a dispersive front member followed by three air-spaced positive singlets while the second component consists of a negative singlet followed by a cemented negative lens member; the third component may be a doublet, whereas the fourth component has heretofore been designed as a single lens. With these previously disclosed systems I have been able to obtain varifocal ratios up to 8:1.

The principal objects of my present invention is to provide an objective system of this general character, to be used in photographic, motion-picture or television cameras, in which the varifocal ratio may be as high as or higher than 10:1 with a relative aperture on the order of 1:2.

Another object is to provide a system of this type whose back-focal length lies about midway within the varifocal range, approximating the individual focal length 4 3,549,235 Patented Dec. 22, 1970 ICC conveniently accommodated between the last vertex and the image plane.

It is also an object of this invention to provide an objective system of the character referred to whose minimum focal length is shorter, preferably by at least 10%, than the image diagonal; with a back-focal length ranging between three and four times the minimum overall focal length of the system, this corresponds to an image angle on the order of 45.

The aforestated objects are realized, in conformity with my present invention, by the provision of an objective system of the above-described type whose first component consists lof one or two dispersive singlets followed by a collective singlet, a dispersive doublet and a group of three air-spaced positive singlets, the second component consisting of a negative'singlet and a negative triplet; the third component is a single dispersive lens member, preferably a doublet consisting of a biconcave lens of relatively high Abb number and a biconvex lens of relatively low Abb number, while the fourth component is composed of two air-spaced collective singlets. As in my above-identified prior disclosures, the individual focal length of the fourth group exceeds (preferably by more than a third) that of the fourth component whereas the absolute value of the individual focal length of the third component exceeds (preferably by at least 10%) that of the second component.

The above and other features of my invention will be described in greater detail with reference to the accompanying drawing in which:

FIGS. 1 and 2 diagrammatically illustrate four representative embodiments; 4

FIGS. 1A and 2A illustrate modifications of the ernbodiments of FIGS. 1 and 2, respectively; and

FIGS. 3-8 are graphs representing the changes in the positions of the movable components of the front attachment throughout the varifocal range for six specific numerical examples.

In FIG. l I have illustrated an optical system according to my invention which comprises a front attachment, consisting of four components I, II, III and IV, and a basic multilens objective V, the two lens groups being separated by a diaphragm D.

Component I, assumed to be limitedly shiftable along the objective axis O for focusing purposes, consists of seven lenses L1 to L7. Lens L1 is a dispersive singlet with radii r1, r2 and thickness d1; it is separated by an air space d2 from lens L2, a collective singlet with radii r3, r4 and thickness d3 which in turn is followed after an air space d1 by a dispersive doublet consisting of positive lens L3 (radii r5, r6 and thickness d5) and negative lens L4 (radii r6, r1 and thickness d6). Another air space dq y separates this doublet from a group of three closely spaced positive singlets, i.e., lens L5 with radii r11, r9 and thickness d8, lens L6 with radii rm, r11 and thickness d10, and lens L7 with radii r12, r13 and thickness :112; the intervening air spaces have been designated dg and d11.

Component II is ofnegative power and is axially shiftable, being separated by a variable air space du from component I. It consists of a negative singlet Le (radii r11, r15 and thickness d1,1) followed, after an air space d15, by a negative triplet composed of a positive meniscus L9 (radii 116, 117 and thickness e116), a biconcave lens L10 (radii r17, r11, and thickness d17) and another positive meniscus L11 (radii rm, r19 and thickness dm).

A further variable air space d1g separates component II from component III which is also of dispersive character and shiftable along the axis; it is a doublet consisting of a biconcave lens L12 (radii r2@l r21 and thickness d20) cemented onto a positive lens L13 (radii 21' r22 and thick- I1SS dgl).

The axially xed fourth component IV, of positive refractivity, follows after another variable air space d22 and consists of a pair of closely spaced positive lenses L11 (radii r22, r2.1l and thickness d23) and L15 (radii :'25, r25 and thickness d25), their separation being designated 124.

The diaphragm space separating the two groups has been indicated at d26.

The basic objective V consists of a positive first lens L15 (radii 127, r22 and thickness i2-1) separated by air space d28 from a negative doublet composed of a positive second lens L12 (radii r29, :'50 and thickness d22) and a biconcave third lens L12 (radii rag, r31 and thickness 130), this doublet in turn being followed after an air space d21 by a positive fourth lens L19 (radii r32, r23 and thickness d22) which is separated by an air space das from a positive doublet composed of a biconvex fifth lens L22 (radii r3.1, r25 and thickness d2.1) and a sixth lens in the form of a negative meniscus L21 (radii r35, r3.; and thickness d35).

In FIG. 2 I have shown a generally similar system which differs from that of FIG. 1 only by the interposition of another negative singlet, i.e., a biconcave len L2, between the negative front lens L1' and the first positive singlet L3' of component I. This component, accordingly, consists of eight lenses L1, to L8, the remaining components Il', III-, IV', and V being unaltered and consisting of lenses L91 to L22. The radii of curvature and the thickness and separations of the system of FIG. 2 have, accordingly, been designated r1, to 158 and d1 O darf'.

Whereas the front component I in FIG l is axially displaceable as a unit for focusing purposes, only the irst three lenses L11, L2' and L3' need to be so displaced in the system 0f FIG. 2.

FIG. 1A shows a modification of the system of FIG. 1 which differs only in the basic objective V, the constituents I", II", III and IV of the varifocal attachment being structurally identical with the corresponding components of'FIG. l and being identified by their radii r1" L12" (radii rw', r21- and thickness d22"), a biconvex fourth lens L12" (radii r32", r35" and thickness 15211), a biconcave fth lens L20" (radii r3.1", r35- and thickness d2.1"), a biconvex sixth lens L21" (radii rw', r21" and thickness d25"), and a positive doublet consisting of a biconvex seventh lens L22" (radii rw', r25" and thickness d22") and a meniscus-shaped negative eighth lens L23" (radii rag", r4.1" and thickness d59"), the intervening air spaces between these six lens members having been designated d22", d21", das", 1351' and i3-1".

In FIG. 2A I show a similar modification of the system of FIG. 2, the constituents I", II", III'" and IV" of the front attachment being structurally identical with the corresponding components of FIG. 2 while the basic objective V" consists of the same eight lenses as the objective V" of FIG. 1A. The lenses L1"' to L24" of this system have radii r1," to r42" vand thicknesses and separations d1", to d.11"-.

The substitution of the eight-lens basic objective V" or V'" for the six-lens objective V or V' results in an increase of the back-focal length of the system which is particularly desirable if the space between the last vertex rw, or r42") and the image plane is to accommodate additional equipment such as prisms P1, P2, P2 (FIG. 1A) or P4' P5 (FIG. 2A) to be used for illuminating the photocathode Of a color-television camera. As indicated in FIG. 2A, a small unsymmetrical biconvex lens L25 may be interposed between the prisms P4 and P5.

The aforestated objects of large varifocal range, high aperture ratio, relatively large back-focal lengthand favorable relationship between minimum focal length and image diagonal are best achieved, pursuant to a more specific aspect of my invention, by adhering to the following design specications for the radii of curvature of the various lenses as related to the individual focal lengths of the components of which they form part. In the varifocal attachment of FIGS. l and 1A, the radii r1 to :'13 (or r1, to r12") of the six-member front component I (or 1") should be related to the individual focal length f1 (or f1") by the inequalities listed below:

The radii r1.1 to r11, (or r1.1" to r19") of the second component II (or 11") should be related to the individual focal length 111 (or full) by the following inequalities:

As to the third component III (or III), the following relationships apply to the radii r21, to r22 (or r20" to r22") and the individual focal length fm (or f111") thereof:

For the fourth component IV (or IV") with its radii r23 to 126 (or r22" to r25") and its individual focal length flv (or f1V") the inequalities are:

In the system of FIG. 2 or FIG. 2A, the radii r1, to r15 (or r1", to r15") of the seven-member front component I' (or I,) are related to the individual focal length f1 (or fIm) thereof as follows:

The relationship between the radii rw to f2s' (or rw. to rgsm) of components Il', III and IV' (or II, III", IV) and their individual focal lengths fn', fmf fw (or fum, fmm, fwm) is the same as with the corresponding components of FIGS. 1 and 1A.

The vradii r2, to ras (or :'29, to ras') of the four lens mem bers of the basic objective V (or V) in FIG. l or 2 should bear the following relationships with the individual focal length fv (or fv) of this basic objective:

The modified basic objective V" (or V") of FIG. lA or FIG. 1B should satisfy the conditions listed below as regards its individual focal length fv'f (or fvm) and the radii r27- to r40- (or r29lto r42m) of its six lens members:

The negative front lens of the rst component is designed toincrease the back-focal length of that group. The distribution of the refractive powers specified above has the purpose of shifting the entrance pupil throughout the varifocal range so far ahead that the diameters of the members of these components, especially of the front lens, may be relatively small. In addition, the relationships set forth afford good correction of all aberrations throughout the operative range.

I shall now list specific numerical values for the radii of curvature and the thicknesses and separations of representative embodiments of the two types of varifocal attachments (in their wide-angle position) and the two types of basic objectives illustrated in the drawing, these parameters being based on a numerical value of unity for the minimum focal length fmm of the system; the tables listing these parameters also set forth the values of the corresponding refractive indices nd and the Abb numbers v. It is to be understood that the tabulated values may vary within tolerances of 120% for the radii as well as the thicknesses and separations, the tolerances for nd being :0.20 and those for the Abb numbers being -5. In view of these tolerances, some of the decimals listed in the tables for the sake of completeness are considered insignificant both for the preferred systems and for the range of tolerances based thereon.

Table I, below releates to the system of FIG. 1. This system has a varifocal ratio of about 11:1, a back-focal length of 3.25 linear units (fmm=1) and a relative aperture of 1:2.0.

TABLE l n Thicknesses Lenses Radu and separations un hd v i rl =0. 378 1.02041 60.

rl2=0. 270 Air s ice L T3=+7. 076 d p d =0. 432 t r5=+431l 492 i Air sp ice L3 (l5: l. 243 1. 620-11 G0. 3

L T= T. 016

4.....- d =0.389 1."2830 '28." 1 rf=+ 11. 535 d d:=1. Air .00 rg=+60- 437 Sp I L5. rls=0. 811 1. 64050 60.1

d=0. 010 Air space rm=l 12. 898 L5 d1o=0. 973 l. G4050 60. 1

d =0. 010 Air s ace nF4-s. 96s l p L1 tllz=0.8l1 1. 64050 60.1

T13= ou d|z=0. 051 Air s ace 1 m=+7. 016 D Ls dr4=0.195 1.69100 54. 7

d =0.Gl3 Airs a e rr rip-5. 871 s p c Lv. fi1=0. 300 1. 80518 25. 4 L r11=3. 220 d r13=+3. 220 l l Ln d1g=0. 378 1. 80518 25. 4

T|g=l8. 552

dw=5. 178 Air space 1 T2u= 2. 513 Ll-g dn=0. 162 1. '1300 53. 8 rrr r..=+2. 705

l d- 2=0. 999 Air space l 11F-33. 759 L14 d23=0. 339 1. 62041 60. 3 Y r24= 3. 7-16 I\y (124:0. 010 Air space T-15=l6. 780 L15 dg5=0. 291 1. 62041 I 60. 3

dgs=0. 054 Air space Tg7=l1.915 Lm dn=0. 699 1. 48606 81.5

Tgg=+77. 541

d:s=0. 632 .Air space rzv= 2. 830 Ln d-3q=0. 704 1. 80588 25. 4

T30=1. 252 Lis d,;0=0. 153 1. 73627 32. 2 T n= +2. 324 V d3i=0.219 Air space T33= +10. 726 Lw d12=0 l141. 1. 48606 81. 5

d;3=0. 038 Air space T34=+2. 495 L 10 d34=0. 546 1. 52122 62. 3

r35= 2. 873 L21 d35=0. 125 1. 78470 26. 1

l Variable.

This objective system may be designed, in practice, for the so-called Plumbikon a frame size of 12.85 x 17.12 mm., with fmm=18 mm. and fmax=20 mm.; the image diagonal is 21.4 mm., thus exceeding by more than the minimum focal length.

Tables II, III and IV relates to the system of FIG. 2.

The system represented by Table II, which has the same image diagonal of 21.4 mm. when used with an actual value of fmm=l8 mm. in connection with the aforementioned frame size, has a relative aperture of The individual focal lengths fr, to fv' of the components listed in Table II have the following values:

fI.=-|7.1222 fH'=-2.4878 HII=4.1577

Cil

. 8 l The law of variation of the air spaces d15', dm' and 24' is plotted in FIG. 4. Specic values, based upon six selected magnitudes of the overall focal length f within its operative range, are listed below:

Variable air spaces [l dts' dri' dei' Table III represents a system with a relative aperture of 1:2.0 and a back-focal length of 3.71 units. When used in connection with a 16-mm. motion-picture film of frame size 77.5 x 10.3 mm., its focal range may extend from fmm=10 mm. to fmax=100 mm.; the image diagonal in that case is 12.74 mm., thus again exceeding the mini mum focal length by more than 10%.

The individual focal lengths fr' to fv of the components listed in Table III have the following values:

The law of variation of the air spaces dis'. dm' and d2., is plotted in FIG. 5. Specific values, based again upon six selected magnitudes of the overall focal length f within its operative range, are listed below:

Variable air spaces f' dis' Table IV represents a modification of the system of Table III, having the same image diagonal when used in the aforementioned range of l-l00 mm.; its relative aperture is 1:2.0 and its back-focal length is 3.26 linear See footnote at cnil ot' table.

TABLE' IV-Comtinned The individual focal lengths f1' to fv' of the components listed in Table IV have the following values:

The law of variation of the air spaces 1151, :121, and dgp listed below:

Variable air spaces f' dis' du' du' is plotted in FIG. 6. Specific values for six positions are Table V relates to the system of FIG. 1A, with a relative aperture of 1:2.0 and a back-focal length of 4.69

Sec footnote nt end ot' table.

LlIlllIS.

TABLE V Thicknesses Lenses Radii and separations na v r1" =55.340 L1..... diff =0.376 1,62041 60. 3

rm =l6.980

d2l =0.269 Air space ry' :+7040 Lz".- d3" =0.753 1,62004 36. 4

du' =0.-130 Air space f5" =+420-278 LWN-.. dy' =1.237 1,62041 60.3

n" =6.980 L4- dw =0.387 1,72830 28. 7 I' f7.. =+11.525

d," =1.129 .Air sp :ce rs" =+60.127 Ls"---.. da" =0.807 1. 64050 60.1

Tg1, 13214 l dw =0.010 Air space r10-=|12.832 La". dw-=0.068 1. 64050 60.1

du-=0.010 Air space ri2"=+8.920 L;- d1-=0.807 1. 64050 60. l

fun:

du-=0.041 Air space l Variable alr spaces dra" die" du" Table VI represents a system as shown in FIG. 2A

with a relative aperture of 112.0 and a back-focal length of 4.84 units.

u The law of variation of the air spaces 71151,, vImm and i 7124,.. is plotted in FIG. 8. Six specic values, based upon 13 selected magnitudes of the overall focal length f", are listed below:

Variable nir spaces The systems of Tables V and VI may be used for the same l6-mm. motion-picture films as those of Tables lll and IV.

The basic objective illustrated in FIGS. 1A and 2A may also be modified by omission of the final doublet L22'l/L23" or L3M/Lum. Thus, according to a further embodiment, components I to IV" may have the numerical values listed in Table I for the Corresponding constituents of FIG. l whereas the truncated basic objective may be designed in accordance with the following data:

Thicknesscs Lenses Radii and Separations nu v r37"=2. -185 La dgr-=0.146 1. 62041 60. 3

rgg-=+5- 408 Lul desi/:0. 368 1. T1736 29. 5

dfg-=0- 12-1 Airspace r,of'=+8. 965 Lis" d30=0. 341 1. 55232 63.5

rl3i-=0. 021 Air space m"=+5. U28 Lig l tl3y1=0-684 1. 51680 I 64. 2

rlj3-=0- 659 Air space rJ,.,=-6 891 L20' rl3i-=0. 151 1. 78470 26.1

dnyf=0.17 Alr space r35"=*ll6. 239 L31' 4 d3"=U. 519 1. 51680 64. 2

Such a system has relative aperture of 12.0 and a backfocal length of 4.45 linear units; the law of variation of its air spaces dw. dlg and (i221. is course, the same as in the system of Table I.

The positive singlet L2 or L3' is designed to compensate the relatively large aberrations occurring at the image-side surfaces of the preceding dispersive singlet or singlets L1 or L1', L21. The collective effect of this positive singlet is partly eliminated in the paraxial zone by the following dispersive doublet whose cemented surface helps suppress the chromatic aberrations, particularly toward the upper end of the varifocal range.

In the three compound lens members of the varifocal attachment, the first lens L3, L12 (or L4', LW) of each doublet and the middle lens L10 (or Lul) of the triplet have a relatively high Abb number as compared with the other lenses cemented thereto. Also, the cemented surfaces of the triplet are both positively refracting whereas that of the first doublet is negatively refracting; the cemented surfaces of the second doublet may be of either positively (Tables I, Il and IV-VI) or negatively refracting (Table III) and, in fact, could also have zero power.

Although the embodiments described and illustrated provide a high degree of correction, particularly for chromatic aberrations, further refinements are possible by substituting compound lenses for some of the singlets and/or by separating the illustrated doublets and triplets into closely spaced individual lenses with confronting surfaces having slightly differing radii of curvature. Such modifications, readily apparent to persons skilled in the art, are intended to be embraced within the spirit and scope of my invention as defined in the appended claims.

I claim:

1. A varifocal objective system comprising a basic multilens objective and a varifocal'front attachment for said objective, said attachment consisting of a substantially xed positive first component, an axially movable negative second component, an axially movable negative third component and a fixed positive yfourth component; said first component consisting of dispersive front lens means, a collective singlet following said front lens means, a dispersive doublet following said collective singlet, and a group of three air-spaced positive singlets following said doublet; said second component consisting of a negative singlet and a negative triplet; said third component consisting of a dispersive lens member; said fourth component consisting of two air-spaced collective singlets; the absolute values of the individual focal lengths of said first and third components substantially exceeding those of said fourth and second components, respectively; said basic objective consisting of a positive first lens, a dispersive doublet composed of a positive second lens and a negative third lens, a positive fourth lens and collective doublet composed of a positive fifth lens and a negative sixth lens; the numerical values of the radii r2, to ras of said first lens L16, said second lens L17, said third lens Lw, said fourth lens L19, said fifth lens L20 and said sixth lens L21, and of the axial thicknesses and separations d2, to d35 thereof, based upon a numerical value of l for a minimum overall focal length of the system, the refractive indices nd of said lenses and their Abb numbers v being substantially as given in the following table:

Lenses Radii aliiiicslgpeatetsions nd v dg=0. 63 Air space d:iu=0. 15 l. 74 32 (131:0. 25 Air space d33=0. 04 Air space da5=l). 13 1. 78 .26

2. A varifocal objective system comprising a basic multilens objective and a varifocal front attachment for said objective, said attachment consisting of a substantially fixed positive first component, an axially movable negative second component, an axially movable negative third component and a fixed positive -fourth component; said rst componentconsisting of dispersive front lens means, a collective singlet following said front lens means, a dispersive doublet following said collective singlet, and a group of three air-spaced positive singlets following said doublet; said second component consisting of a negative singlet and a negative triplet; said third component consisting of a dispersive lens member; said fourth component consisting of two air-spaced collective singlets; the absolute values of the individual focal lengths of said first and third components substantially exceeding those of 'said fourth and second components, respectively; said said first lens L17', said second lens L18', said third lens L19', said fourth lens L20', said fifth lens L21', and said sixth lens L22', and of the axial thicknesses and separations 129' to d3',' thereof, based upon a numerical value of 1 for a minimum overall focal length of the system, the refractive indices nid of said lenses and their Abb numbers 1' being substantially as given in the following table:

3. A varifocal objective system comprising a basic multilens objective and a varifocal front attachment` for said objective, said attachment consisting of a substantially f'ixed positive first component, an axially movable negative second component, an axially movable negative third component and a fixed positive fourth component; said first component consisting of dispersive front lens means, a collective singlet following said front lens means, a dispersive doublet following said collective singlet, and a group of three air-spaced positive singlets following said doublet; said second component consisting of a negative singlet and a negative triplet; said third component consisting of a dispersive lens member; said fourth component consisting of two air-spaced collective singlets; the absolute values of the individual focal lengths of said first and third components substantially exceeding those of said fourth and second components, respectively; said basic objective consisting of a positive first lens, a dispersive doublet composed of a positive second lens and a negative third lens, a positive fourth lens and a collective doublet composed of a positive fifth lens and a negative sixth lens; the numerical values of the radii r29' to r38' of said first lens L17', Said second lens L13', said third lens L19', said fourth lens L20' said fifth lens L21' and said sixth lens L22', and of the axial thicknesses and separations d29' to dav' thereof, based upon a numerical value of l for a minimum overall focal length of the system, the refractive indices nd of said lenses and their Abb numbers v being substantially as given in the following table:

4. A varifocal objective system comprising a basic multilens objective and a varifocal front attachment for said objective, said attachment consisting of a substantially fixed positive first component, an axially movable negative second component, an axially movable negative third component and a fixed positive fourth component; said first component consisting of dispersive front lens means, a collective singlet following said front lens means, a dispersive doublet following said collective singlet, and a group of three air-spaced positive singlets following said doublet; said second component consisting of a negative singletand a negative triplet; said third component consisting of a dispersive lens member; said fourth component consisting of two air-spaced collective singlets; the absolute values of the individual focal lengths of said first and third components substantially exceeding those of said fourth and second components, respectively; said basic objective consisting of a positive first lens, a dispersive doublet composed of a positive second lens and a negative third lens, a positive fourth lens and a collective doublet composed of a positive fifth lens and a negative sixth lens; the numerical values of the radii r29' to ras' of said rst lens L17', said second lens L18', said third lens L19', said fourth lens L20', said fifth lens L21' and said sixth lens L22', and of the axial thicknesses and separations d29' to dm' thereof, based upon a numerical value of 1 for a minimum overall focal length of the system, the refractive indices nd of said lenses and their Abb numbers v being substantially as given in the following table:

5. A varifocal objective system comprising a basic multilens objective and a varifocal front attachment for said objective, said attachment consisting of a substantially fixed positive first component, an axially movable negative second component, an axially movable negative third component and a fixed positive fourth component; said first component consisting of dispersive front lens means, a collective singlet following said front lens means, a dispersive doublet following said collective singlet, and a group of three air-spaced positive singlets following said doublet; said second component consisting of a negative singlet and a negative triplet; said third component consisting of a dispersive lens member; said fourth component consisting of two air-spaced collective singlets; the absolute values of the individual focal lengths of said first and third components substantially exceedingthose of said fourth and second components, respectively; said basic objective consisting of a dispersive doublet composed of a negative first lens and a positive second lens, a positive third lens, a positive fourth lens, a negative fifth lens, a positive sixth lens and a collective doublet composed of a positve seventh lens and a negative eighth lens; the numerical values of the radii r2?, to 140 of said rst lens L16", said second lens L11', said third lens L18-, said fourth lens L19", said fifth lens Lw, said sixth lens L21H, said seventh lens L22', and said eighth lens L21', and of the axial thicknesses and separations d2?, to dag/- thereof, based upon a numerical value of 1 for a minimum overall focal length of the system, the refractive indices nd of said lenses of their Abb numbers v being substantially as given in the following table:

6. A varifocal objective system comprising a basic multilens objective and a varifocal front attachment for said objective, said attachment consisting of a substantially fixed positive rst component, an axially movable negative second component, an axially movable negative third component and a fixed Apositive fourth component; said first component consisting of dispersive front lens means, a collective singlet following said front lens means, a dispersive doublet following said collective singlet, arid a group of three air-spaced positive singlets following i' said doublet; said second component consisting of a negative singlet and a negative triplet; said third component consisting of a dispersive lens member; said fourth component consisting of two air-spaced collective singlets;

' the absolute values of the individual focal lengths of said first and third components substantially exceeding those of said fourth and second components, respectively; said basic objective consisting of a dispersive doublet composed of a negative first lens and a positive second lens, a positive third lens, a positive fourth lens, a negative fifth lens, a positive sixth lens and a' collective doublet composed of a positive seventh lens and a negative eighth lens; the numerical values of the radii rzgm to 1112"' of said first lens L17-'1, said second lens L18m, said third lens L19m, said fourth lens LW, said fifth lens L21m, said sixth lens Lgzm, said seventh lens Lzam and said eighth lens LMI", and of the axial thicknesses and separations d29fto du," thereof, based upon a numerical value of l for a minimum overall focal length of the system, the refractive indices nd of said lenses and their Abb numbers v being substantially as given in the following table:

7. A varifocal objective system comprising a basic multilens objective and a varifocal front attachment for said objective, said attachment consisting of a substantially fixed positive -first component, an axially movable negative second component, an axially movable negative third component and a fixed positive fourth component; said iirst component consisting of dispersive front lens means, a collective singlet following said front lens means, a dispersive doublet following said collective singlet, and a group of three air-spaced positive singlets following said doublet; said second component consisting of a negative singlet and a negative triplet; said third component consisting of a dispersive lens member; said fourth component consisting of two air-spaced collective singlets; the absolute values of the individual focal lengths of said first and third components substantially exceeding those of said fourth and second components, respectively; said basic objective consisting of a dispersive doublet composed of a negative first lens and a positive second lens, a positive third lens, a positive fourth lens, a negative fifth lens and a positive sixth lens the numerical values of the radii r27- to raw of said iirst lens LW, said second lens Lw, said third lens L18H, said fourth lens 1.19,, said fifth lens L20, and said sixth lens L211', and of the axial thicknesses and separations dm', to dw thereof, based upon a numerical valueof 1 for a minimum overall focal length of the system, the refractive indices nd of said lenses and their Abb numbers if being substantially as given in the following table:

Thicknesses Lenses Radii and separations 'mi v rg7-=-2.5 Lie f d21-=0.l5 1.62 60 r:s"=+5.4 LU" I d2g"=0.37 1. T2 30 myc-11.4

d2g-=0.l2 Air space ri-=+9-0 i L15 d30"=0,34 1. 55 64 d3w=0.02 Air space T32=+5.9 LW' dgp/:0.68 1. 52 64 d=066 Air space rivm-6.9 L10" d31-=0.15 1. 79 26 1115..:018 Air spi` ce 1 r31-=+16-2 L21" d35l1=0.52 1. 52 64 Turc-4.0

8. A varifocal objective system comprising a basic multilens objective and a varifocal front attachment for said objective, said attachment consisting of a substantially `fixed positive first component, an axially movable negative second component, an axially movable negative third component and a fixed positive fourth component; said first component consisting of a dispersive first lens L1, a collective second lens L2, a dispersive doublet composed of a positive third lens L3 and a negative fourth lens L4, a positive fifth lens L5, a positive sixth lens L5 and a positive seventh lens L7; said second component consisting of a negative eighth lens L8 and a negative triplet composed of a positive ninth lens L9, a biconcave tenth lens L10 and a positive eleventh lens L11; said third component consisting of a dispersive doublet composed of a biconcave twelfth lens L12 and a positive thirteenth lens L13; said fourth component consisting of a collective fourteen lens L14 and a collective fifteenth lens L15, the numerical Values of the radii r1 to f2s of said lenses L1 to L15 and of the axial thicknesses and separations d1 to d thereof, based upon av numerical value of 1 for a minimum overall focal length of the system, the refractive indices nd of said lenses and their Abb numbers v being substantially as given in the following table:

Thicknesses Lenses Radii and separations 'nd M T1 55. 6 Li di =0. 38 1. 62 60 Tz ='l7. 0

d2 =0. 27 Air space T3 =|7. 1 Lz Y d; =0. 76 1. 62 36 di =0.- 43 Air space rg, =+431. 5 La d5 =1. 24 1.62 60 Ie =7. 0 L4 di =0. 39 1. 73 29 dy l. 14 Air space Ts +60. 4 L; da =0. 81 1. 64 60 rg= -l3. 3

dq =0. 01 Air space v T1a= +12. 9 La d1=0. 97 1. 64 60 d11=0. 01 Air space T11: +9. 0 L1 d12=0. 81 1. 61

d13=0. 05 Air space 1 n4= +7. 0 Lg d11=0. 20 1.69 55 d1s= 0. 64 Air space r1s= 5. 9 Lg d11=0. 30 1. S1 25 Tn= 3. 2 Lm d17=0. 20 1. 71 54 r1s= +3. 2 L11 d1s=0. 38 1.81 25 dn=5. 18 Air spacci Tzo= 2. 5 L12 +0 d:n=0. 1G 1. 71 54 rn= 7 L11 d1=0. 42 1. 72 29 dz2= 1. 00 Air space i T2s= *33. 8 L14 dz3=0. 34 1. 62 60 d24=0. 01 Air space Tz5= +6. 8 Lis d25= 0. 29 1.62 6U 1 Variable.

9. A varifocal objective system comprising a basic multilens objective and a varifocal front attachment for said objective, said attachment consisting of a substantially fixed positive first component, an axially movable negative second component, an axially movable negative third component and a fixed positive fourth component; said first component consisting of a dispersive first lens L1-, a collective second lens L2, a dispersive doublet composed of a positive third lens Ly and a negative fourth lens L41, a positive fifth lens L5-, a positive sixth lens L6 and a positive seventh lens L7-; said second component consisting of a negative eighth lens LW and a negative triplet composed of a positive ninth lens LgH, a biconcave tenth lens L10I and a positive eleventh lens L11-; said third component consisting of a dispersive doublet composed of a biconcave twelfth lens L12- and a positive thirteenth lens L15; said fourth component consisting of a collective fourteenth lens L12 and a collective fifteenth lens L15; the numerical values of the radii r1' to r25- of said lenses L1 to L15, and of the axial thicknesses and separations d1 to d25- thereof, based upon a numerical value of 1 for a minimum overall focal length of the system, the refractive indices nd of said lenses and their Abb numbers v being substantially as given in the following table:

Thicknesses Lenses Radii and separations nd t Ti"=55.3 L1" dw=0.38 1. 62 60 d2"=0.27 Air space r3-=l7.0 L2" d1-=0.75 1. 62 36 d4-=0.43 Air space r5-=+429.3 L31 d5-=1.24 1. 62 60 n-=7.0 L1" di"=0.39 1. 73 29 d1-=1.13 .Air space ra"=+60.1 L51 dg-=0.81 1. 64 60 nw=l3.2

dv-=0.0l Air space r1o"=+l2.8 La" dm"=0.97 1. 64 60 rn"=23.0 I

d11"=0.01 Air space r12"=l8.9 L11' d12-=0.81 1. 64 60 d13"=0.04 Air space l m"=l7.0 La', d14"=0.19 1. 69 55 di5"=0.64 Air space rn"=-5.8

d1s-=0.30 1.81 25 r1r"=3.2

d17"=0.19 1. 71 54 rie"=+3.2

di"=0.38 1. 81 25 T19"=+8.5

dw'=5.16 Air space 1 Tgo"=2.5 Lic" d-g0'f=0.16 1. 71 54 r21"= 2.7 L13'I dgw=0-42 1, 72 29 dn"=0.99 Air space l T23"=33.6 L14" dg3/'=0.34 1. 62 60 d:w=0.01 Air space r25"=-l6.7 L15 1125":020 1. 62 60 Tte"=+33.6

1 Variable.

10. A varifocal objective system comprising a basic multilens objective and a varifocal front attachment for said objective, said attachment consisting of a substantially fixed positive first component, an axially movable negative second component, an axially movable negative third component and a' fixed positive fourth component; said first component consisting of a dispersive first lens L1, a dispersive second lens L2', a collective third lens L3, a dispersive doublet composed of a positive fourth lens L4 and a negative fifth lens L5, a positive sixth lens L5, a positive seventh lens L7' and a positive eighth lens L21; said second component consisting of a negative ninth lens L91 and a negative triplet composed of a positive tenth lens L10', a biconcave eleventh lens L11, and a positive twelfth lens L12; said third component consisting of a dispersive doublet composed of a biconcave thirteenth lens L13' and a positive fourteenth lens 1.14'; said fourth component consisting of a collective fifteenth lens L15' and a collective sixteenth lens Lm'; the numerical values of the radii r1' to f2s' of said lenses L1' to L16' and of the axial thicknesses and separations d1' to 1127' thereof, based upon a numerical value of l for a minimum overall focal length of the system, the refractive indices nd of said lenses and their Abb numbers 1' being substantially as given in the following table:

Thicknesses Lenses Radii and separations nd v r1'=l6l3.0 L1' +8 8 d1'=0.29 1, 62 60 di'=1.30 Air space ry=11.5 La' d3f=0.29 l. 62 60 +14 5 dy=0.05 An' space r5'= La' 32 3 d5'=0.69 1. 66 33 d'=0.27 Air space r1'=+1s4.6 L4' 6 d1'=1.16 1. 71 54 rg'=-5. L5' dg'=0.27 1. 73 29 rta/:+268

+81 6 dg'=0.20 Air space riu= La' 9 1 1 d10'=0.78 1. 64 5U +11 9 dn'=0.01 Air space f L1' m 431 4 (1..':058 1.64 6o +6 3 d13'=0.01 Air space n Lt 4 +15 8 d,.'=o.e5 1. e4 so 15 0 d151=0.03 Air space l r 1= 7. La' M dw=0-20 1. 69 55 5 l d17'=0.69 Air space r L' a 3 l '1.,':027 1. s1 25 T19'= Lil' +3 l d1n'=0.20 1. 71 54 12 L1.' +8 6 d.'=o.ss 1. s1 25 4 di1'=5.21 Air space l T2'=-2. L13' Z d22'=.16 1. 7l 54 T23'=+3.3 L14' 15 o d23'=0.42 1. 72 29 i 8 dz4'=0.92 Air space l T2'=33. L1.' d.5'=o.34 1. s1 l et 2 +6 dw=0.01 Air spa ce T 7'= .7 LW 2 d'=o.29 1.51 es ngc-19.4

l Variable.

11. A varifocal objective system comprising a basic multilens objective and a varifocal front attachment for said objective, said attachment consisting of a substantially fixed positive first component, an axially movable negative second component, an axially movable negative third component and a fixed positive fourth component; said first component consisting of a dispersive first lens L1', a dispersive second lens L2', a collective third lens L3', a dispersive doublet composed of a positive fourth lens L4' and a negative fifth lens L5', a positive sixth lens Le', a positive seventh lens L7 and a positive eighth lens La'; said second component consisting of a negative" ninth lens L9' and a negative triplet composed of a positive tenth lens L10', a biconcave eleventh lens L11' and a positive twelfth lens Llz'; said third component consisting of a dispersive doublet composed of a biconcave thirteenth lens L13' and a positive fourteenth lens Lw; said fourth component consisting of a collective fifteenth lens L' and a collective sixteenth lens Lm'; the nu- 22 merical values of the radii r1' to rzg' of said lenses L1' to L16' and of the axial thicknesses and separations d1' to dm' thereof, based upon a numerical value of 1 for a minimum overall focal length of the system, the refracl tive indices nd of said lenses and their Abb numbers v being substantially as given in the following table:

Thicknesses Lenses Radi and separationsl nd v r1f=l291.3 L1y dvr-0.29 1. 62 60 da' =1.29 Air space Ts =11.7 L2y da =0.29 1.62 60 d4' =0.05 Air space T5' =+14.7 L3' d5' =0.72 1.66 33 da' =0.22 Air space r1' =88.2 L4' d1' =1.36 1. 71 54 rs' =`-5.6 L5' da' =0.22 1. 73 29 de' =0.19 Air space r1o'=+70.1 La' d10'=0.87 1. 64 60 dn=0.01 Air space T12'=i12.4 L7' d12'=0.66 1. 64 60 dum-0.01. Air space Tu'=l6.0 Lg' d14=0.68 1. 64 60 d15=0.08 Air space l r1e'=+5.3 L9 d1s'=0.19 1. 69 55 dr1'=0.78 Air space r1s'=5.0 Lw' d1g'=0.30 1. 81 25 T19'= 3.4 L11' d1a'=0.19 1. 7l. 54

r2u'=l3.4 L12' d20'=0.38 1. 8l. 25

d2,.=4.83 Air space l r22'=-2.8 L13' d22'=0.19 1. 71 54 r23'=+3.6 L14' dz3'=0.39 1.69 31 (124:1,65 Air space l T25'=i14.6 L15' dg5'=0.34 1. 53 5l.

d1'=0.01 Air space T27'=l4.4 L10' dg7'=0.29 1. 52 60 r2s'=ll8.7

l Variable.

12. A varifocal objective system comprising a basic multilens objective and a varifocal front attachment for said objective, said attachment consisting of a substantially fixed positive first component, an axially movable negative second component, an axially movable negative third component and a fixed positive fourth component; said first component consisting of a dispersive first lens L1', a dispersive second lens L2, a collective third lens L3, a dispersive doublet composed of a positive fourth lens L4' and a negative fifth lens L5', a positive sixth lens L6', a positive seventh lens L7' and a positive eighth lens La'; said second component consisting of a negative ninth lens L9 and a negative triplet composed of a positive tenth lens L10', a biconcave eleventh lens L11' and a positive twelfth lens L12'; said third component consisting of a dispersive doublet composed of a biconcave thirteenth lens L13' and a positive fourteenth lens LM'; said fourth component consisting of a collective fifteenth lens L15 and a collective sixteenth lens Lw; the numerical values of the radii r1' to r28' of said lenses L1' to L16' and of the axial thicknesses and separations d1' to dm' thereof, based upon a numerical value of l for a minimum overall focal length of the system, the refractive indices nd of said 23 lenses and their Abb numbers u being substantially as given in the following table:

Thicknesscs Lenses Radii and separations n.1 v

nl =+288- Li' +8 6 di' =0. 29 1.,(32 6() n G d1' :1.28 Air spice r1' Lz' +19 8 d3' =0..29 1.62 6() +14' s d4f=0. 05 All' space T5' t La' 31 di' =0. 72 1.66 32 do' =0. 22 Air space f7l= 6 dr =l.35 1.71 i rs' =5.

+28 4 3s' =0. 22 1. 73 .J Tp' +69 4 du' =0. 19 Air space T101: La 9 2 d10=0.87 1.64 G0 3 d11f=0. 01 Airspace T12= L7' 16 o d1g1=0. 65 1. 64 60 +6 3 dw=0.01 Air space T14'= La' +15 6 d14l=0. 67 1. 54 G0 +6 9 d15'=0. 10 Air space 1 rw= Lg' +o 4 dw=0. 19 1. 69 55 1 di1'=0. 68 Air space fla/=5. L10' 3 1 d1g'=0. 27 1. 8l. 25

m'= L11' +3 dw=0. 19 1. T1 54 T20l= l. L12' +8 dg0'=0. 35 1.81 25 4 dw=5-12 Air spat-cl T22'=-2. L13' +3 d22'=0. 16 1. 71 51 r- .4 L1" 23 3 dg3'=-O. 41 1. 72 29 33 d24f=0. 94 Air space l f25l= .9 L15' 3 7 d25l=0. 34 1. 51 64 o d2/=0. 01 Air space T27'= 6... l L14' 4 g d311=0. 29 1. 5l. 64

T2s'=f 7 lVariable.

13. A varifocal objective system comprising a basic multilens objective and a varifocal front attachment for said objective, said attachment consisting of a substantially xed positive first component, an axially movable negative second component, an axially movable negative third component and a lixed positive fourth component; said first component consisting of a dispersive rst lens L11", a dispersive second lens Lgf", a collective third lens 1.4m, a dispersive doublet composed of a positive fourth lens L4", and a negative fth lens L51", a positive sixth lens L5M, a positive seventh lens L7," and a positive eighth lens Lam; said second component consisting of a negative ninth lens 1.9m and a negative triplet composed of a positive tenth lens Lmm, a biconcave eleventh lens Lum and a positive twelfth lens Lum; said third component consisting of a dispersive doublet comn Thicknesses Lenses Radu and separations na u r1m=+554- 9 L1' d1"=0. 26 l. 62 60 dy"=1. 17 Air space ry-=-10. 4 y LW alma 26 1. 62 60 d4'-=0. 04 Air space r5"'=+13. 2 Lgf'y d51-=0.62 1.66 i 33 Tgm=29. 2

df-=0. 25 Air space r1-f=l167. 1 L,... d1f-=1.05 1.71 54 r5f-=5. 1 Ly" d@'-=0. 25 1. 73 29 dqf-=0. 18 Air space r101-= +73. 9 Lgf" d10"'=0. 7l. 1. 64 50 d1i"'=0. 01 Air space Tx2"'=ll0. 7 L11" d12f-=0. 53 1. 64 60 d13l-=0. 01 Air space T14"'=+5. 7 Lg'l d14"'=0. 59 l. 64 60 dwf/=0. 03 Air space l m,=+6 3 Lgf" drill/=0. 18 l. 69 55 d11"'=0. 62 Air space Tiam=4. 6 LW" d1-1=0 25 1. 81 25 119111:-2' 8 Lun: dnl/1:0,18 1. 71 54 720.,.:4-2, g Lulu dnl/1:0, 32 1. 81 25 dnl-=0. 47 Air space 1 r22m=2. 2 Lw" dg2'f/=O. l5 1. 71 54 m"'=l3. 0 Lw" duf/'=O. 38 1. 72 29 r2i"'=l3. 8

dg4f-=0. 83 Air space l www-30. 6 1415"' d25"'=0. 31 1, 51 64 1 func-3.4 dz5l-=0. 01 Air space ,wm-p6. 5 Lw" d-g1-=0. 26 1. 51 G4 1 Variable.

References Cited FOREIGN PATENTS 82,637 2/1964 France 350-184 1,030,462 5/1966 Great Britaln4 350-184 1,108,935 6/1961l Germany 350-184 DAVID SCHONBERG, Primary Examiner PAUL A. SACHER, Assistant Examiner 

